Computer readable storage medium for work-in-process schedules

ABSTRACT

A computer readable storage medium for work in progress (WIP) schedules in semiconductor manufacturing facility. After determining starting and ending dates of predetermined schedule periods for generating WIP schedules, remaining days are determined for completing at least one wafer lot associated with predetermined product from the starting date. A starting process stage for the wafer lot is determined at the starting date based on the remaining days, and an ending process stage for the wafer lot at the end of the ending date. Wafer numbers are assigned to each process stage of schedule times in proportion to process times of each stage in view of total process time for the schedule period, and by repeating the above steps for one or more other wafer lots under production, a total wafer number assigned to each stage is determined and the WIP schedule for the schedule period is obtained.

RELATED APPLICATION

This application is a divisional application of U.S. Pat. applicationSer. No. 10/840,099, filed on May 6, 2004, the contents of which arehereby incorporated by reference as if set forth in their entirety.

BACKGROUND

This invention relates to semiconductor fabrication and, moreparticularly, to computer readable storage media for planning operationswithin semiconductor fabrication facilities.

In a large manufacturing facility, such as a semiconductor foundry inwhich many tools are required to build the wafer and chip product, thereare complex programs that run the tools that require monitoring andcontrol to guide manufacturers in the way these programs may beimplemented. The main framework for this system is known as the ComputerImplemented Manufacturing (CIM) framework.

The overall control of the foundry floor is by a central server having aManufacturing Execution System (MES) with tool control system. Thecentral server has the information on each customer job that iscurrently being processed and ensures that each tool in sequence isperforming the correct operation. This server communicates with userswho monitor and control the production flow and operations on clientworkstations.

Standard work-in-progress (WIP) profiles or schedule, by process stage,are one of the items that manufacturing personnel and managers wouldlike to know most. Even though WIP profiles are popular, there is nosystematic method to generate a WIP profile in a timely and consistentmanner. One problem with generating WIP profiles is that a significantamount of data about process time and cycle time factor must becollected, organized, correlated, and maintained. Maintaining, let alonecollecting and correlating, this information in a timely manner requiressignificant resources and support by Fabrication Plant and InformationTechnology personnel.

Desirable in the art of is a need for a method and system for timelydetermining WIP profiles to allow for efficient operation ofsemiconductor foundries in order to maximize the capacity of themanufacturing facility.

SUMMARY

In view of the foregoing, this invention provides a method and programfor generating a work in progress (WIP) schedule in a. semiconductormanufacturing facility.

In some embodiments, a computer readable storage medium encoded withcomputer program code, wherein, when the computer program code isexecuted by a processor, the processor performs a method for generatinga work in progress (WIP) schedule in a semiconductor manufacturingfacility. After determining the starting and ending dates of apredetermined schedule period for generating the WIP schedule, remainingdays are determined for completing at least one wafer lot associatedwith a predetermined product from the starting date. A starting processstage for the wafer lot is determined at the beginning of the startingdate based on the remaining days, as well as an ending process stage forthe wafer lot at the end of the ending date. Wafer numbers are assignedto each process stage of the schedule time in proportion to a processtime of each stage in view of a total process time for the scheduleperiod; and, by repeating the above steps for one or more other waferlots under production, a total wafer number assigned to each stage isdetermined and the WIP schedule for the schedule period is obtained.

The construction and method of operation of the invention together withadditional objects and advantages thereof will be best understood fromthe following description of specific embodiments when read inconnection with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 presents a diagram illustrating wafer process time with respectto each process stage and relevant time lines in accordance with oneembodiment of the present invention.

FIG. 2 illustrates a flow diagram for detailed steps for generating theWIP schedule in accordance with one embodiment of the present invention.

DESCRIPTION

The following is a detailed description of an improved method forgenerating WIP schedules so that a manufacturing facility can maximizeits capacity in accordance with the present invention. The disclosedmethod assigns wafer numbers to each stage of the manufacturing based onprocess time needed for each

stage. In semiconductor manufacturing, an order of certain productsneeds to be started from blank wafers, and goes through various stagesof processes in the manufacturing process. In a manufacturing facility,a large number of orders are going through various stages of thefacility at any time, and it is noted that an order may be split intomultiple wafer lots.

In planning semiconductor fabrication, information may be collected ordrawn from a Management Executive System (MES) which may be acommercially available or a user-generated software package suitable forretaining and maintaining information items associated withsemiconductor fabrication, such recipes, process steps, etc. The datamay be provided to a planning software for creating the productionschedule, e. g., the WIP schedule, for fabrication of the semiconductorproducts wafers. The resultant plan or schedule may include informationregarding, for embodiment, forecast of how many wafers should bemanufactured for each stage of the fabrication process, and may alsoinclude other production related information about material consumption,mask requirements, etc.

Table I below illustrates that an order or a batch of product havingpart identifier (ID) A goes through processing stages 44 through 50 forits entire manufacturing time period. Also listed is the net processingtime needed in each stage, and the corresponding accumulative processtime as the wafers go through the flow. TABLE I Accumulated Process TimeProcess Time Part ID Stage_ID Stage Order (Days) (Days) A Stage_50 500.40 0.4 A Stage_49 49 0.62 1.02 A Stage_48 48 0.29 1.31 A Stage_47 470.11 1.43 A Stage_46 46 0.21 1.64 A Stage_45 45 0.31 1.95 A Stage_44 440.23 2.17As it is understood, that, although the net total accumulative processtime is about 2.17 days, but due to the production reality, it isusually scheduled for more time for the entire manufacturing process.For embodiment, the total time scheduled can be 3 days. The relationbetween the total time scheduled and the net total accumulative processtime can be mathematically represented by a ratio referred to as an Xratio for this invention:X=Total Scheduled Time/Total Accumulative Process TimeIt is further noted although mathematical representations are made abovein Table I with regard to each stage, it is understood that once aprocess starts in any stage, it has to finish and cannot instantly stopat any arbitrary time.

When generating a WIP schedule, it is usually done on a daily basisduring the production process. Since the schedule can change every day,the WIP scheduling can be done multiple times on an as-needed basis.Further, one or more computing devices can be used for processinginformation to generate the WIP schedule.

FIG. 1 illustrates, graphically, time schedules of the process flow 100for a particular product. In this exemplary case, the net process timeassociated with each stage_ID shown in Table I is depicted sequentiallyalong a linear time line 110. The net process time associated with eachstage_ID is further shown underneath each stage. FIG. 1 furtherillustrates the association of a remaining process time line 120 withrespect to each stage as the process flow progresses. For embodiment, atthe beginning of a starting stage 44, total 2.17 days are remaining forfinishing the flow, and similarly, at the end of stage 44, 1.94 days areleft.

When generating a WIP schedule for a coming day, it is first determinedwhich stage the process flow shall be started for the day. The due datefor completing the product is also determined. It then can be calculatedhow many days are left for production. For embodiment, if the due dateis 7/4/04, and it is 7/2/04, that needs a WIP schedule. There are total3 remaining days for processing. Using the X ratio, it can be obtainedthat the process should start at point 3/2=1.5 on the process time line120. This point is identified as point 130. As it is described above,the stages of processes are discrete in nature, and the identified point130 only indicates that the process should start from the next stage,e.g., stage 47.

Once the starting stage for the day is determined, the ending stage alsoneeds to be determined. At the end of 7/2/04, there are only 2 daysremaining so that 2 divided by the X ration to get 1 reflected by point140 on the time line 120, which is stage 49. It is further determinedthat the total daily process time for these three stages is0.11+0.29+0.62=1.02 days. Now, it is all determined how many stages theWIP schedule should cover for the day under scheduling. Wafer numbersneed to be assigned to each stage for scheduling WIP purpose. Assumingthe same product has a plurality of wafer lots going through theproduction flow and each wafer lot may have different number of wafers.Assuming a wafer lot has 50 wafers, the wafers are distributed inproportion to the net process time with respect to the total dailyprocess time. In this particular embodiment, for stage 47,50×0.11/1.02=5.39 wafers should be assigned. This process should berepeated for all wafer lots involved for the product to get a totalnumber of wafers assigned for stage 47. Since wafers cannot be divided,the total number of wafers has to be rounded. For embodiment, 15.39wafers have to be rounded to 15 or 16 wafers based a roundingconvention. As such, a WIP schedule for the product for thepredetermined day is generated. When every wafer lot is considered forthe product, the scheduling may extend to other products as well so thatthe total usage of each stage can also be identified.

FIG. 2 illustrates a process 200 for determining a WIP schedule inaccordance with one embodiment of the present invention. In step 210, astarting date to be scheduled is obtained as determined by the user.Although the embodiments illustrated above or below use a daily WIPschedule for illustration, the WIP schedule can be set for any length oftime. For embodiment, if a work flow takes a month, a high level weeklyWIP may be scheduled in addition to daily schedules.

Assuming only daily WIP is needed, in step 220, a due date is obtained.In step 230, the starting stage of the day is determined based on acycle time factor, referred to as the “X ratio,” and the total daysremaining for the process flow. The X ratio helps to scale the remainingdays so that a time point can be identified on the remaining time lineas illustrated in FIG. 1. Alternatively, the starting stage can bedetermined based on the ending stage of the day immediately previous tothe day under scheduling. In step 240, the ending stage of the day isalso determined. When all the process stages are identified for the day,the total number of wafers in wafer lots for predetermined products areused for determining the number of wafers assigned to each stage basedon the net process time of each stage with respect to the total dailyprocess time. The WIP schedule is now completed (step 260) and variousreports can be generated.

Such a WIP generating process can be implemented using computerprocessing tools. Software programs can be developed to provideinstructions and interfaces for generating the WIP schedule. Theplatform for developing such a software can be chosen based on thesoftware environment of the existing manufacturing facility. One skilledin the art can understand that the above described functions forgenerating the WIP schedule can be developed using various softwaretools. With the networking technology in existence today, the WIPschedule can be generated, viewed, modified, or otherwise controlled byauthorized users.

The present invention may be embodied in the form of computer-implemented processes and apparatus for practicing those processes. Thepresent invention may also be embodied in the form of computer programcode embodied in tangible media, such as floppy diskettes, read onlymemories (ROMs), CD-ROMs, DVDs, hard drives, ZIP™ disks, memory sticks,or any other computer-readable storage medium, wherein, when thecomputer program code is loaded into and executed by a computer, thecomputer becomes an apparatus for practicing the invention. The presentinvention may also be embodied in the form of computer program code, forexample, whether stored in a storage medium, loaded into and/or executedby a computer, or transmitted over some transmission medium, such asover the electrical wiring or cabling, through fiber optics, or viaelectromagnetic radiation, wherein, when the computer program code isloaded into and executed by a computer, the computer becomes anapparatus for practicing the invention. When implemented on ageneral-purpose processor, the computer program code segments configurethe processor to create specific logic circuits.

While the invention has been described with reference to the preferredembodiments thereof, it will be appreciated by those of ordinary skillin the art that modifications can be made to the parts that comprise theinvention without departing from the spirit and scope thereof, asdefined by the claims. It is expressly intended that all combinations ofthose elements that perform substantially the same function insubstantially the same way to achieve the same results are within thescope of the invention. Substitutions of elements from one describedembodiment to another are also fully intended and contemplated.

1. A computer readable storage medium encoded with computer programcode, wherein, when the computer program code is executed by aprocessor, the processor performs a method for generating a work inprogress (WIP) schedule in a semiconductor manufacturing facility,comprising the steps of: receiving starting and ending dates of apredetermined schedule period for generating the WIP schedule;determining remaining days for completing at least one wafer lotassociated with a predetermined product from the starting date;determining a starting process stage for the wafer lot at the beginningof the starting date based on the remaining days; determining an endingprocess stage for the wafer lot at the end of the ending date; assigningwafer numbers to each process stage between the starting and the endingprocess stages of the schedule time in proportion to a process time ofeach stage in view of a total process time for the schedule period; andgenerating the WIP schedule for the schedule period after repeating theabove steps for one or more other wafer lots under production todetermine a total wafer number assigned to each stage.
 2. The computerreadable storage medium of claim 1, wherein the starting dates and theending dates are the same.
 3. The computer readable storage medium ofclaim 1, wherein the step for determining a starting process stagefurther includes steps of: receiving a process time for each processstage to complete the wafer lot; and identifying the starting processstage along a remaining process time line indicating remaining time forcompleting the wafer lot based on the determined remaining days and atotal process time for completing the wafer lot.
 4. The computerreadable storage medium of claim 3, wherein the step for identifying thestarting process stage further includes steps of: scaling the remainingdays by a cycle time factor to obtain a time point; and determining thestarting process stage by identifying the time point along the remainingprocess time line.